Title :
CMOS Fluorometer for Oxygen Sensing
Author :
Guo, Jian ; Zhang, Jingjing ; Thomas, Samuel ; Sonkusale, Sameer
Author_Institution :
Dept. of Electr. & Comput. Eng., Tufts Univ., Boston, MA, USA
fDate :
7/1/2012 12:00:00 AM
Abstract :
This letter presents an integrated complementary metal-oxide semiconductor fluorometer that utilizes frequency-domain fluorescence lifetime imaging spectroscopy for oxygen-sensing applications. The implemented fluorometer chip consists of a p+/n-well/p-substrate photodiode, a phase readout circuit with integrated zero-crossing detection to extract the frequency-domain phase shift into a time-domain delay, and a high-resolution time-to-digital converter for digital quantization of the converted time delay. The fabricated fluorometer consumes less than 8.3 mW power and has a temporal resolution of 110 ps. During oxygen-sensing experiments, a ruthenium complex was used as an oxygen-sensitive dye whose lifetime was measured as a function of the of the oxygen concentration in water.
Keywords :
CMOS integrated circuits; chemical sensors; oxygen; reliability; frequency- domain phase shift extraction; frequency-domain fluorescence lifetime imaging spectroscopy; high-resolution time-to-digital converter; integrated CMOS fluorometer; integrated complementary metal-oxide semiconductor fluorometer; integrated zero-crossing detection; oxygen concentration; oxygen sensing applications; phase readout circuit; power 8.3 mW; time 110 ps; time delay digital quantization; time-domain delay; water; CMOS integrated circuits; Delay effects; Frequency domain analysis; Frequency modulation; Imaging; Luminescence; Sensors; Fluorescence lifetime imaging spectroscopy; fluorometer; low power; oxygen sensing; photodiode; ruthenium complex; time-to-digital converter; zero-crossing detection;
Journal_Title :
Sensors Journal, IEEE
DOI :
10.1109/JSEN.2012.2194280
